Touch screen finger position indicator for a spinal cord stimulation programming device
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A61N-001/00
A61N-001/372
G06F-003/0354
G06F-003/044
출원번호
US-0011156
(2013-08-27)
등록번호
US-9180302
(2015-11-10)
발명자
/ 주소
Drees, Scott
Kaula, Norbert
Iyassu, Yohannes
Leyh, Scott G.
Polefko, Richard J.
Trier, Stephen C.
Yoder, Raymond L.
출원인 / 주소
Greatbatch Ltd.
대리인 / 주소
Haynes & Boone, LLP
인용정보
피인용 횟수 :
13인용 특허 :
130
초록▼
A method of visualizing a user interaction with a clinician programmer is disclosed. A user engagement with respect to a screen of the clinician programmer is detected via one or more sensors associated with the screen of the clinician programmer. One or more locations on the screen of the clinician
A method of visualizing a user interaction with a clinician programmer is disclosed. A user engagement with respect to a screen of the clinician programmer is detected via one or more sensors associated with the screen of the clinician programmer. One or more locations on the screen of the clinician programmer corresponding to the user engagement is determined. An external monitor is communicatively coupled to the clinician programmer. The external monitor displays one or more cursors that graphically represent the one or more locations on the screen of the clinician programmer corresponding to the user engagement, respectively.
대표청구항▼
1. A clinician programmer, comprising: a touch-sensitive screen configured to display visual content to a health care provider;one or more sensors configured to detect an engagement from the health care provider with respect to the screen;a transceiver configured to conduct telecommunications with a
1. A clinician programmer, comprising: a touch-sensitive screen configured to display visual content to a health care provider;one or more sensors configured to detect an engagement from the health care provider with respect to the screen;a transceiver configured to conduct telecommunications with an external monitor that is multiple times larger than the clinician programmer;a memory storage component configured to store programming instructions; anda computer processor configured to execute the programming instructions to perform the following tasks: detecting, via the one or more sensors, the engagement from the health care provider with respect to the screen;determining one or more locations on the screen corresponding to the health care provider's engagement; andsending signals, via the transceiver, to the external monitor to display one or more cursors on the external monitor, the one or more cursors graphically representing the one or more locations on the screen of the clinician programmer corresponding to the health care provider's engagement, respectively. 2. The clinician programmer of claim 1, wherein the tasks further comprise mirroring the displaying of the one or more cursors on the screen of the clinician programmer. 3. The clinician programmer of claim 1, wherein the one or more sensors include a touch sensor, and wherein the detecting comprises detecting a physical contact of the screen of the clinician programmer via the touch sensor. 4. The clinician programmer of claim 3, wherein the detecting the physical contact comprises detecting a physical contact from a finger or a stylus. 5. The clinician programmer of claim 1, wherein the one or more sensors include a proximity sensor, and wherein the detecting comprises detecting a proximity of a finger or a stylus via the proximity sensor. 6. The clinician programmer of claim 1, wherein the engagement from the health care provider invokes an action on the clinician programmer, and wherein the displaying comprises graphically differentiating a selected one of the cursors from the rest of the cursors, wherein the selected one of the cursors corresponds to the invoked action. 7. The clinician programmer of claim 1, wherein the displaying is performed in a manner such that a majority of an area covered by the cursors is transparent. 8. The clinician programmer of claim 1, wherein the clinician programmer is configured to program a pulse generator so that the pulse generator delivers an electrical stimulation therapy to a patient. 9. A medical system, comprising: a monitor; anda clinician programmer located remotely from the monitor, the clinician programmer being configured to program parameters of an electrical stimulation therapy for a patient, the clinician programmer including: a touch-sensitive screen configured to display visual content to a health care provider;one or more sensors configured to detect an engagement from the health care provider with respect to the screen;a transceiver configured to conduct telecommunications with the monitor;a memory storage component configured to store programming instructions; anda computer processor configured to execute the programming instructions to perform the following tasks: detecting, via the one or more sensors, the engagement from the health care provider with respect to the screen;determining one or more locations on the screen corresponding to the health care provider's engagement; andsending signals, via the transceiver, to the monitor to display one or more cursors on the monitor, the one or more cursors graphically representing the one or more locations on the screen of the clinician programmer corresponding to the health care provider's engagement, respectively. 10. The medical system of claim 9, further comprising a pulse generator programmable by the clinician programmer to deliver the electrical stimulation therapy to the patient. 11. The medical system of claim 9, wherein the tasks further comprise mirroring the displaying of the one or more cursors on the screen of the clinician programmer. 12. The medical system of claim 9, wherein the one or more sensors include a touch sensor, and wherein the detecting comprises detecting a physical contact of the screen of the clinician programmer via the touch sensor. 13. The medical system of claim 12, wherein the detecting the physical contact comprises detecting a physical contact from a finger or a stylus. 14. The medical system of claim 9, wherein the one or more sensors include a proximity sensor, and wherein the detecting comprises detecting a proximity of a finger or a stylus via the proximity sensor. 15. The medical system of claim 9, wherein the engagement from the health care provider invokes an action on the clinician programmer, and wherein the displaying comprises graphically differentiating a selected one of the cursors from the rest of the cursors, wherein the selected one of the cursors corresponds to the invoked action. 16. The medical system of claim 9, wherein the displaying is performed in a manner such that a majority of an area covered by the cursors is transparent. 17. The medical system of claim 9, wherein the monitor is multiple times larger in size than the clinician programmer. 18. An apparatus for visualizing an interaction associated with a health care provider, the apparatus comprising: means for detecting an engagement from the health care provider with respect to a screen of a clinician programmer, the clinician programmer being configured to program a pulse generator so that the pulse generator delivers an electrical stimulation therapy to a patient;means for determining one or more locations on the screen of the clinician programmer corresponding to the engagement from the health care provider; andmeans for displaying or more cursors that graphically represent the one or more locations on the screen of the clinician programmer corresponding to the engagement from the health care provider, respectively, wherein the means for the displaying is remotely located from, and communicatively coupled to, the clinician programmer. 19. The apparatus of claim 18, further comprising means for mirroring the displaying of the one or more cursors on the screen of the clinician programmer. 20. The apparatus of claim 18, wherein the means for detecting comprises a touch sensor for detecting a physical contact of the screen of the clinician programmer, the physical contact being made by a finger or a stylus. 21. The apparatus of claim 18, wherein the means for detecting comprises a proximity sensor for detecting a proximity of a finger or a stylus. 22. The apparatus of claim 18, wherein the engagement from the health care provider invokes an action on the clinician programmer, and wherein the means for displaying comprises means for graphically differentiating a selected one of the cursors from the rest of the cursors, wherein the selected one of the cursors corresponds to the invoked action. 23. An electronic device, comprising: a touch-sensitive screen configured to display visual content to a health care provider;one or more sensors configured to detect an engagement from the health care provider with respect to the screen;a radio configured to establish a communications link between the electronic device and an external monitor, wherein the external monitor has a display that is larger than the touch-sensitive screen;a memory storage component configured to store programming instructions; andone or more computer processors configured to execute the programming instructions to perform the following steps: detecting an engagement from the health care provider with respect to the touch-sensitive screen via the one or more sensors;determining one or more locations on the touch-sensitive screen corresponding to the engagement from the health care provider; andcausing the external monitor to display one or more cursors that graphically represent the one or more locations on the touch-sensitive screen, respectively. 24. The electronic device of claim 23, wherein the steps further comprise: displaying the one or more cursors on the touch-sensitive screen. 25. The electronic device of claim 23, wherein the one or more sensors include a touch sensor, and wherein the detecting comprises detecting a physical contact of the touch-sensitive screen via the touch sensor. 26. The electronic device of claim 25, wherein the detecting of the physical contact comprises detecting a physical contact from a finger or a stylus. 27. The electronic device of claim 23, wherein the one or more sensors include a proximity sensor, and wherein the detecting comprises: detecting a proximity of a finger or a stylus via the proximity sensor. 28. The electronic device of claim 23, wherein the engagement from the health care provider invokes an action on the electronic device, and wherein the external monitor graphically differentiates a selected one of the cursors from the rest of the cursors, wherein the selected one of the cursors corresponds to the invoked action. 29. The electronic device of claim 23, wherein the external monitor displays the one or more sensors in a manner such that a majority of an area covered by the cursors is transparent. 30. The electronic device of claim 23, wherein the touch-sensitive screen is multiple times smaller in size than the external monitor. 31. The electronic device of claim 23, wherein the electronic device is physically separated from the external monitor in different rooms. 32. The electronic device of claim 23, wherein the electronic device is configured to program a pulse generator so that the pulse generator delivers an electrical stimulation therapy to a patient.
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Stone, Richard T.; Ball, Warren W.; Wahlstrand, Carl D.; Goetz, Steven M.; Otten, Lynn M., Electrical and activation field models for configuring stimulation therapy.
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Powers Daniel J. ; Cameron David ; Cole Clinton S. ; Lyster Thomas D. ; Mydynski Steven T. ; Morgan Carlton B., External defibrillator with automatic self-testing prior to use.
Forsberg, John W.; Palm, Jeffry C.; Wosmek, Mark G.; Deininger, Steven T.; McMullen, Raymond F.; Michaels, Matthew J.; Kelly, Kevin J., External presentation of electrical stimulation parameters.
Goetz, Steven M.; Johnson, Donald R.; Drew, Touby A.; Houchins, Andrew H.; Keacher, Jeffrey T.; Stone, Theodore J.; Roberts, Earle T., Medical device programming safety.
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Woods, Carla M.; Thacker, James R.; Peterson, David K.; Segel, Holly A.; Ford, Susan E.; Theriot, Margaret E.; Bradley, Kerry, Method for programming implantable device.
Skelton, Dennis M.; Davis, Jon P.; Sahasrabudhe, Rajeev; Gokaldas, Shyam; Nolan, Joseph J.; Bourget, Dennis; Bourget, Duane; Miesel, Keith A.; Zimmerman, James, Modification profiles for posture-responsive therapy.
Bolea, Stephen L.; Hoegh, Thomas B.; Persson, Bruce J.; Atkinson, Robert E.; Hauschild, Sidney F.; Kaplan, Paula M.; Kuhnley, Brian D.; Jasperson, Keith E.; Tesfayesus, Wondimeneh; Thorp, Christopher K., Obstructive sleep apnea treatment devices, systems and methods.
Juran Carleen J. ; Yakimow Kristin ; Shelton Michael B. ; Stroebel John C. ; Markowitz H. Toby ; Vatterott Pierce ; Strandquist Harry A., Pacemaker implant recognition.
Nappholz Tibor A. ; Steinhaus Bruce ; Chiang Chih-ming James ; Bernstein Alan D., Pacemaker programmer menu with selectable real or simulated implant data graphics.
Fischell, David R.; Harwood, Jonathan; Johnson, Steven R.; Fischell, Tim A., Physician's programmer for implantable devices having cardiac diagnostic and patient alerting capabilities.
Epstein Andrew E. (Birmingham AL) Duncan James L. (Alpharetta GA) Levine Paul A. (Santa Clarita CA) Sholder Jason A. (Beverly Hills CA), Programming system having means for recording and analyzing a patient\s cardiac signal.
Juran Carleen J. ; Busacker James W. ; Shelton Michael B. ; Brynelsen Charles R. ; Edery Thomas P. ; Wahlstrand John D., Resetting ERI/POR/PIR/indicators in implantable medical devices.
McMenimen, James L.; Campbell, Christopher J.; Ruble, Barbara K.; Fabian, Willa M.; Clark, Larry G.; Thompson, David L., Responsive manufacturing and inventory control.
Chaouat,Laurent Francois, Self-adaptive system for the automatic detection of discomfort and the automatic generation of SCS therapies for chronic pain control.
Migdal, Alexander; Lebedev, Alexei, System and method for computer modeling of 3D objects or surfaces by mesh constructions having optimal quality characteristics and dynamic resolution capabilities.
Persen, Kenneth H.; Vallapureddy, Vineel, System and method for providing communications between a physically secure programmer and an external device using a cellular network.
Pless, Benjamin D.; Fischell, David R.; Gibb, Barbara; Guzzo, Lisa; Upton, Adrian R. M., Systems and methods for interacting with an implantable medical device.
Whitehurst,Todd K; Makous,James C; Carbunaru,Rafael; Jaax,Kristen N, Systems and methods for treatment of diabetes by electrical brain stimulation and/or drug infusion.
Goetz, Steven M.; Keacher, Jeffrey T.; Sahasrabudhe, Rajeev; Dewing, Wende L.; Davis, Jon P.; Rondoni, John; Miyazawa, Gabriela C.; King, Gary W., User interface with toolbar for programming electrical stimulation therapy.
Agashiwala, Julie; Choudhry, Lindsey M., Computer display panel with graphical user interface comprising a set of images for fashion ensemble planning.
Saad Ahmed, Ahmed Aly; de Vries, Evert; Elseaidy, Wael, Display screen with transitional graphical user interface for a medical image data processing application.
Saad Ahmed, Ahmed Aly; de Vries, Evert; Elseaidy, Wael, Display screen with transitional graphical user interface for a medical image data processing application.
Verma, Ajay; Bober, Marisa J.; Cabot, Victoria; Hilliard, Courtney D.; Knaian, Ara N.; Newburg, Seth O.; Hoppin, John William; Schmidt, Karl F., Wearable medical detector.
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